Bit-efficient control information for use with multimedia streams

ABSTRACT

Bit efficient control information communication techniques. Control information for configuring an audiovisual device to present multimedia content may be generated. The control information may be organized according to a tree data structure having a plurality of nodes. The control information may include commands for navigating the nodes of the tree structure to locate data values stored at leaf nodes of the tree structure. Some commands may have associated data fields. Each command, and each data field, may include bit portions of uniform length. A designated bit of command bit portions may have a first value indicating that the bit portion is a command, while a designated bit of data field bit portions may have a second value indicating the bit portion is a data field. The second value may be different than the first value.

PRIORITY CLAIM

This application is a continuation of U.S. application Ser. No.12/479,423 titled “Transmitting and Receiving Control Information foruse with Multimedia Streams, filed on Jun. 5, 2009, which claims benefitof priority to provisional application Ser. No. 61/131,165 titled“Enhanced Mobile TV System with Extensibility” filed on Jun. 7, 2008,and which is a continuation-in-part of U.S. application Ser. No.12/167,708 titled “Mobile Television Broadcast System” filed on Jul. 3,2008, which claims benefit of priority to provisional application Ser.No. 60/948,185 titled “Robust Mobile TV Broadcast System” filed Jul. 5,2007, Ser. No. 60/958,585 titled “Robust Mobile TV Broadcast System”filed Jul. 5, 2007, and Ser. No. 60/999,039 titled “Robust Mobile TVBroadcast System” filed Oct. 14, 2007, all of which are herebyincorporated by reference in their entirety as though fully andcompletely set forth herein.

FIELD OF THE INVENTION

The present invention relates to configuring a communication system, andmore specifically in one embodiment to a reconfigurable method forsignaling configuration information.

DESCRIPTION OF THE RELATED ART

In traditional communication systems, the format of the data and controlstreams can only be changed in predefined ways. A few bits are reservedfor adding functionality, a few enumerated parameters support multipleoptions, but overall the changes supported are very limited. Thedevelopers add this limited flexibility to the system in places theythink are likely to change. There are two types of changes needed thatcannot be planned for; unforeseen problems with the system and newtechnology innovations. Support for indeterminate change requiresforwards compatibility.

Flexible, extensible methods of structuring data have been invented toaddress the need for a data and control protocol that can evolve overtime, but they have limitations. Such languages include XML, JSON andYAML. These languages structure data in a tree based format, which isadvantageous for extensibility, but can require significant overhead ifnot carefully designed for bit efficiency. The format of the XML andrelated protocols is text based to support human readability. Thisallows the data to be human readable, but burdens the language withexcessive overhead. In communication systems, bandwidth efficiency ishighly desirable. A much more efficient method of extensiblecommunication is needed.

The ATSC (Advanced Television Systems Committee) standard relates to adigital television format which will replace the analog NTSC televisionsystem. The ATSC standard is a high definition television standard thatproduces standard 4:3 or wide screen 16:9 images up to 1920×1080 pixelsin size—more than six times the display resolution of the earlier NTSCstandard. The ATSC standard makes provisions to transport multiplestandard-definition “virtual channels” broadcast on a single 6 MHz TVchannel. The ATSC standard also includes “theater quality” audio usingthe Dolby Digital AC-3 format to provide 5.1-channel surround sound. TheATSC standard also provides numerous auxiliary datacasting services.Improvements are needed in the signaling and versioning of the ATSCstandard.

SUMMARY OF THE INVENTION

Embodiments of the invention relate to a system and method forgenerating control information for use in transmission with a multimediastream to an audiovisual device. Embodiments of the invention alsorelate to a system and method for receiving and presenting multimediacontent according to received control information. Embodiments of theinvention may be used with digital mobile broadcast television, as wellas provision of digital multimedia content to various mobile/handhelddevices, such as cell phones, smart phones, etc.

In a transmission embodiment, the method generates one or more groups(e.g., a plurality of groups) of control information. Each group ofcontrol information is for configuring the audiovisual device to presenta multimedia stream. Each group of control information may be generatedaccording to a different protocol version. Further, each group ofcontrol information may be for configuring the audiovisual device topresent the multimedia stream in a different manner.

The method may also generate a first data structure (which may bereferred to as a service descriptor). The first data structure compriseslocation information of each group of control information. The firstdata structure may also specify the protocol version for each group ofcontrol information. Locations of each of the plurality of groups ofcontrol information may be based on protocol version and/or servicetype. The first data structure may be configured to be extensible, e.g.,to add additional information which relates to additional controlinformation. For example, additional control information may be added toaccommodate future standard changes, or new standards, and the firstdata structure can be extended accordingly to include informationregarding this new control information. Also, additional data structures(service descriptors) may be included in subsequent transmissions toaccommodate additional control information.

The information contained in the first data structure is useable byreceiving audiovisual devices to determine which control information iscompatible with the audiovisual device, and which control informationshould be ignored.

The method may then generate and transmit a first plurality of packets,the first plurality of packets comprising the first data structure, theplurality of groups of control information, and a multimedia stream.Here the “transmission” of packets includes broadcast transmission ofpackets, such as in a wireless broadcast television system. The“transmission” of packets also includes provision of packets from aserver computer to a client (e.g., a mobile device) over a network, suchas the Internet.

The first data structure may be used by the audiovisual device to ignoreone or more respective groups of control information if the audiovisualdevice is not configured to understand the protocol version(s) of theone or more respective groups of control information.

In a reception embodiment, an audiovisual device may receive a firstplurality of packets, wherein the first plurality of packets comprise afirst multimedia stream, first control information, second controlinformation and a first data structure. The packets may be received in awired or wireless manner.

The first data structure (e.g., service descriptor) comprises locationinformation for the first control information and the second controlinformation. The first data structure also specifies a first protocolversion of the first control information and a second protocol versionof the second control information.

The audiovisual device analyzes the first data structure to determinethe location information for the first control information and thesecond control information, and the first and second protocol versionsof the first control information and the second control information.Where the audiovisual device is not configured to understand the secondprotocol version, the audiovisual device uses the location informationof the second control information to ignore the second controlinformation.

The audiovisual device then configures itself according to the firstcontrol information, thus enabling the audiovisual device to present thefirst multimedia stream. The audiovisual device may then present thefirst multimedia stream after being configured.

The control information, which is provided to the audiovisual device forconfiguring the audiovisual device to present a multimedia stream, maybe organized according to a tree data structure having a plurality ofnodes, wherein at least some of the nodes are leaf nodes. The leaf nodesstore data values for configuring the audiovisual device. The controlinformation may comprise a plurality of commands. At least some of thecommands are executable by the audiovisual device to navigate the nodesof the tree structure to locate the data values stored at the leafnodes. Certain of the commands may be executable to navigate the treestructure relative to a current position in the tree structure.Alternatively, or in addition, certain of the commands may be executableto navigate the tree structure relative to a root node of the treestructure. One or more of the commands may be a modifier command. Themodifier command may specify a parameter value for all leaf nodes belowa current node position in the tree data structure. For example, themodifier command may specify that all data values below the current nodeposition in the tree data structure are optional data values, or aremandatory values. Some of the leaf nodes may each store a plurality ofdata values for configuring the audiovisual device.

In one embodiment, the control information comprises a plurality ofcommands, wherein at least a subset of the commands have associated datafields. One or more of the commands may be a modifier command includinga length value and which specifies a parameter value applied to all datavalues within a length distance from the modifier command specified bythe length value. For example, the modifier command may specify that alldata values within the length distance from the modifier commandspecified by the length value are optional data values, or are mandatoryvalues.

Embodiments of the invention may utilize various bit efficiencies tomore efficiently generate the control information. For example, thecontrol information may comprise a plurality of commands, wherein atleast a subset of the commands has associated data fields. Each of thecommands may comprise a plurality of bit portions of a uniform length.Also, each of the data fields may comprise a plurality of bit portionshaving uniform length. In one embodiment, a first bit (such as the MSB)of the bit portions of the commands may have a first value (e.g., a “0”)indicating that the bit portion is a command. A first bit (such as theMSB) of the bit portions of the data fields may have a second value(e.g., a “1”) indicating that the bit portion is a data field, whereinthe second value is different than the first value. This provides anefficient way to indicate length of commands and data, without requiringa dedicated length field.

BRIEF DESCRIPTION OF THE DRAWINGS

A better understanding of the present invention can be obtained when thefollowing detailed description of the preferred embodiment is consideredin conjunction with the following drawings, in which:

FIG. 1 illustrates a digital television broadcast system according toone embodiment;

FIG. 2 is a flowchart diagram illustrating a method for generatingcontrol information for use in transmission with a multimedia stream toan audiovisual device according to one embodiment;

FIG. 3 is a flowchart diagram illustrating a method for an audiovisualdevice to receive control information for a multimedia stream accordingto one embodiment;

FIG. 4 is an illustration of an architecture with in-line signalingaccording to one embodiment;

FIG. 5 is an illustration of a tree based data structure according toone embodiment;

FIG. 6 is an illustration of the base version functional blocks of theATSC M/H system according to one embodiment;

FIG. 7 is an illustration of a tree based data structure encompassingversioning for ATSC M/H functional blocks according to one embodiment;

FIG. 8 is an illustration of an architecture with a separate versioningblock according to one embodiment;

FIG. 9 is an illustration of an architecture with a combined versioningand signaling block according to one embodiment;

FIG. 10 is an illustration depicting a packet format according to oneembodiment;

FIG. 11 is a table defining the fields of a control packet according toone embodiment;

FIG. 12 is an illustration of the format of the service descriptor fieldaccording to one embodiment;

FIG. 13 is a table defining the sub-fields of the service descriptorfield according to one embodiment;

FIG. 14 is a table illustrating an exemplary service descriptor fieldaccording to one embodiment;

FIG. 15 is an illustration of the format of a series of commands/dataaccording to one embodiment;

FIG. 16 is a table defining an XCL command set according to oneembodiment;

FIG. 17 is a table defining XCL command set modifiers according to oneembodiment;

FIG. 18 is an illustration depicting part of an ATSC M/H tree accordingto one embodiment;

FIG. 19 is an illustration depicting an ATSC M/H tree according to oneembodiment;

FIG. 20 is an illustration depicting a FIC data tree for use with theATSC M/H tree in FIG. 19 according to one embodiment;

FIG. 21 is an illustration depicting an exemplary command sequencenavigating a FIC tree according to one embodiment;

FIG. 22 is an illustration depicting a SMT data tree for use with theATSC M/H tree in FIG. 19 according to one embodiment;

FIG. 23 is an illustration depicting an exemplary command sequencenavigating an SMT tree according to one embodiment;

FIGS. 24 and 25 are tables defining alternate embodiments of an XCLcommand set and command modifiers;

FIGS. 26-28 are illustrations depicting alternate embodiments of FIC andSMT data trees.

While the invention is susceptible to various modifications andalternative forms, specific embodiments thereof are shown by way ofexample in the drawings and are herein described in detail. It should beunderstood, however, that the drawings and detailed description theretoare not intended to limit the invention to the particular formdisclosed, but on the contrary, the intention is to cover allmodifications, equivalents and alternatives falling within the spiritand scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF THE INVENTION

A communication system, such as a broadcast system, may typicallyinclude a framework for communicating some sort of content orservice(s). A communication system may additionally include a signalingframework to provide information to receivers about the content orservice(s). Any communication system with even minimal complexity orwhich may be expected to change over time may need to provide suchinformation to enable a receiver to use the content or service(s); forexample, a signaling framework may enable a receiver to tune to anoffered service, to extract the service from the transport, and presentit to a user. One specific example of a communication system is anaudiovisual broadcast system, e.g., a digital television broadcastsystem. Many of the embodiments described herein may be illustrated inlight of such an exemplary system, although the embodiments may also beapplicable to other communication systems.

Signaling may include information on specific components which may beuseful or necessary for a receiver to use a service Signaling may alsoinclude versioning information. One or more components of the system (atany level of the system, up to and including the entire system) mayinclude a protocol version. A receiver may need to know such versioninginformation in order for it to reconstruct a service correctly. Forexample, if a service is constructed at a transmitter with a version offunctionality newer than the current functionality installed on thereceiver, the receiver may not be able to process the service andpresent it correctly. The version information for the functionalityinvolved in the processing and presentation of the service may thereforeneed to be included in the signaling information. Because bandwidth in acommunication system may be limited, it may also be important that thesignaling framework be efficient, e.g., in order to preserve as muchbandwidth as possible for the actual content and/or service(s).

The signaling framework and methodology used in a given communicationsystem will have a significant effect on the forward and backwardcompatibility of present and future implementations of the communicationsystem. A particularly desirable feature for a communication system isto be able to provide for older (legacy) devices and services while atthe same time being able to provide new services and devices capable ofsupporting the new services. The most effective way to efficientlyprovide this backward compatibility in new services (e.g., to developnew services and devices which can operate alongside legacy devices andservices) may be to build a signaling framework that is very forwardcompatible (e.g., that is designed to efficiently and effectivelyprovide for indeterminate change to the communication system, includingin the signaling framework itself). Thus, using a flexible, extensible,and efficient signaling framework can be critical to improving theoverall functionality of a communication system as well as extending theuseful lifespan of components (e.g., services offered and consumercomponents for receiving those services) of the communication system.

Various embodiments of the present invention relate to such a frameworkand methodology which may produce a flexible, extensible, and efficientversioning and signaling system for a communication system. One key tosuch a framework may be to provide a way for legacy receivers togracefully recognize if they can't support a portion of thesignaling/version data and ignore or skip such portions of thesignaling/versioning data. This allows more freedom in the developmentof new services and receivers which can support those new serviceswithout crippling a legacy receiver's ability to receive content.

There may be several components to such a framework which may each beimplemented in various ways. Some or all of these components may worktogether to produce an extensible and efficient signaling and versioningframework. In some embodiments, one or more of the components may beimplemented individually, e.g., without the other components, althoughin some embodiments, greater benefit may be derived from using some orall of the components together. The components may include any of thefollowing, each of which will be described further below. There may be ameans for structuring the signaling/versioning data such that theinsertion of unsupported data in the structure can be detected andskipped gracefully by legacy receivers. There may be a means ofpartitioning the signaling/versioning data into compatible groups, suchthat targets of these groups (e.g., receivers) may support thefunctionality grouped. There may be a means of indexing into thesesignaling/versioning groups such that receivers are supported inaccessing only the data required to decode and correctly present asupported service, and so that they may know in advance of attempting topresent content, that the presentation of the content is fullysupported. There may be a means for determining how much data is to beskipped if some portion is unsupported. There may be a means fornavigating or otherwise referencing the structure of thesignaling/versioning data such that the structure of data can be amendedand/or extended. There may be a means for extending the means ofnavigating or otherwise referencing the structure of thesignaling/versioning data.

Structuring the signaling/versioning data such that the insertion ofunsupported data in the structure can be detected and skipped gracefullyby legacy receivers means that the structure includes, for each portionof the structure which is likely to be modified independently of anyother portions of the structure, an element that signals to receivers(i.e., including legacy receivers) whether or not they are able tosupport that portion of the structure. Effectively, there must be a wayto mark different portions of the structure by version. This may be donein a number of ways. One implementation involves structuring thesignaling/versioning data in a tree format, where any given leaf or node(e.g., including one or more leaves and/or sub-nodes) may be versionedindividually. Another implementation includes structuring thesignaling/versioning data in one or more tables, where each portion of atable has a header or a pointer which directly or indirectly marks theversion of that portion of the signaling/versioning data. In addition,the structure itself should be extensible, that is, there must be a wayto insert additional signaling/versioning data. A tree structure lendsitself easily to this additional requirement, as additional nodes orleaves can be created without affecting the remainder of the structure.A table may also be able to accommodate this requirement.

Partitioning the signaling/versioning data into compatible groups, suchthat targets of said groups may support the functionality grouped, mayincrease the efficiency of the signaling framework. Examples of suchgroupings could include protocol version of a given standard, class ofservice, audio/visual information type, standard type, etc. For example,if the signaling/versioning data is partitioned into protocol versiongroups, a receiver compatible up to a particular protocol version mayget all of the signaling/versioning data for that protocol version froma single group.

Indexing into the signaling/versioning groups may allow a receiver tofind a group which it supports, and conversely, to recognize groupswhich it cannot support, and thus ignore them. As compared to forcing areceiver to begin parsing the signaling/versioning data itself in orderto discover whether or not that data is supported, this may be a muchmore efficient way for a receiver to discover which portion(s) of thesignaling/versioning data are relevant to and supported by thatparticular receiver. One exemplary implementation of such an index is a‘service descriptor’ or a ‘service discovery table’, e.g., a datastructure separate from the signaling/versioning data, which providessuch indexing information. Another possible implementation is to includesuch indexing information within the signaling versioning data, althoughthis may provide less flexibility for future changes to the signalingframework itself.

If a receiver is to skip or ignore unsupported data, it must have a wayto determine how much data is to be skipped. In other words, a receivermay not only need to be able to recognize that it doesn't support aportion of the data, it may also need to know where the data to beskipped begins and ends. In one embodiment, this may be built into theindexing functionality, for example, an index may include informationlocating the beginning and end of each group. In some embodiments,although a group may have the same base protocol version, it may bedesirable to include some optional components with a different (e.g., ahigher) protocol version in the group. In this case, a way of markingthese components as optional may also be desirable.

The means for navigating or otherwise referencing the structure of thesignaling/versioning data such that the structure can be amended and/orextended may be useful in order to make future protocol versionrevisions and new protocol versions of the communication system. Forexample, if the structure is a tree structure, the means for navigatingthe tree must include the ability to navigate to new or amended nodes orleaves in the tree; otherwise, the means for navigating the tree cannotsupport an amended tree. In one implementation, this may be a set ofcommands for navigating the tree structure which supports navigating toany node or leaf of the tree. An example of such a command set isdescribed in more detail with respect to FIGS. 15-17. Such a command setis referred to herein as an “extensible control language” or “XCL”.Whatever structure is used for the signaling/versioning data, (e.g.,tree, table, or any structure), the means for navigating or otherwisereferencing it should allow for amendments and/or extensions to thatstructure.

Similarly, it may be useful to provide a means for extending the meansfor navigating or otherwise referencing the structure. In other words,the signaling method itself should be flexible and extensible. This maybe as simple as reserving a fixed number of bits or values for futurenavigation or referencing information, however, an indefinitelyextensible system may be preferable. As an example, consider again thetree based structure described above for the signaling/versioning data,and the command set for navigating the tree. Any given command in thecommand set might be enumerated as a value in a fixed length field.Instead of reserving a few values of the field for unknown future use,and being limited (within that signaling protocol version) to those fewvalues for any new commands, a command may be defined for extending thefield by another fixed increment. The extended field may be used for newcommands until all values of the extended field are defined, and thefield may again be extended by the ‘extend field’ command; this maycontinue indefinitely without breaking backward compatibility.

Embodiments and exemplary implementations of such an extensiblesignaling framework are described below with respect to a broadcastsystem, e.g., a digital television broadcast system. It should again benoted, however, that while the methods described herein may be used withbroadcast systems, such as depicted in FIG. 1 and described belowaccording to various embodiments they may also be used more generally,e.g., with any communication system where appropriate.

FIG. 1—Digital Television Broadcast System

FIG. 1 illustrates an exemplary broadcast system 100 according to oneembodiment of the invention. In one embodiment, the broadcast system maybe a digital television broadcast system. The broadcast system 100described herein, including the various methods described herein, may beused for broadcasting any of various types of data, includingaudiovisual information as well as other data. The term “broadcast” asused herein is intended to encompass the full range of its ordinarymeaning, as understood by one of skill in the art.

As used herein, the terms “audiovisual information” and “multimediastream” include any of various types of information or data thatcomprises video data and/or audio data. The term “video data” includesmotion video (such as television, movies, streaming video, etc.), aswell as image data, such as JPEGs. The terms “audiovisual information”and “multimedia stream” further include any of various types ofinformation or program instructions that, when executed, cause a deviceto present video data (on a display) and/or audio data (on speakers).For example, the terms “audiovisual information” and “multimedia stream”include any of various types of gaming content (including programinstructions and/or data) that can be used and/or executed to presentgaming content (e.g., images, video, and/or audio) on a presentationdevice.

In one set of embodiments, the broadcast system may operate according tothe ATSC (Advanced Television Standards Committee) standard, e.g., using8-VSB modulation. Alternatively, the broadcast system may operateaccording to a modified version of the ATSC standard, or according toanother standard. For example, the Mobile/Handheld (M/H) modification ofthe ATSC standard is used for transmission of audiovisual informationfor moving receivers. Specific examples of the embodiments disclosedherein may be based on, or include portions of the M/H modification tothe ATSC standard, and may also include further variations andmodifications to M/H and the ATSC standard. However, the embodimentsrelated to transmission of audiovisual information disclosed herein arenot necessarily limited to use with the ATSC or M/H systems, and may beequally applicable for transmission of audiovisual information inaccordance with other standards and/or modulations schemes, such asDVB-T/H, ISDB-T, DMB-T/H, etc.

As shown, the system 100 comprises a transmission system (or transmitsystem) 102, and one or more audiovisual devices (e.g., one or morestationary devices such as 112A, and/or one or more mobile devices suchas 112B-112E). As noted above FIG. 1 is exemplary only, e.g., anexemplary system may comprise one or more transmission systems 102, aplurality of mobile devices, and a plurality of stationary devices. Anyof the various methods described herein may be utilized with eithermobile devices or stationary devices, or both, as desired.

The transmission system 102 may be configured to transmit audiovisualinformation to the one or more audiovisual devices 112 in a wired or awireless manner. In a particular embodiment, the transmission system 102may be configured to transmit digital television signals/channelswirelessly to the mobile devices 112B-112E. The mobile devices 112B-112Emay receive and present the audiovisual information, e.g., receive andpresent the digital television signals/channels. The transmission system102 may also be configured to transmit audiovisual information to thestationary device 112A (e.g., stationary television), either in a wiredor a wireless manner. In some embodiments, an audiovisual device may beable to act as a transmission system; for example, an audiovisual devicemight be able to receive a transmission and re-broadcast it locally toother audiovisual devices. Thus, in some embodiments, the transmissionsystem 102 may also be an audiovisual device.

The transmission system 102 comprises a transmitter 106 as well astransmit logic 104 coupled to the transmitter 106. The transmit logic104 may comprise any of various types of logic, such as one or morecomputer systems (with accompanying software), digital logic, analoglogic, programmable gate arrays, etc., or combinations thereof. Thetransmit logic 104 is adapted for receiving and/or storing audiovisualinformation (e.g., television data) and for generating packetscontaining the audiovisual information. The transmit logic 104 maygenerate packets according to any of various standards, such as the ATSC(Advanced Television Standards Committee) standard, e.g., using 8-VSBmodulation. The transmission system 102 may use other modulationschemes, such as DVB-T/H, ISDB-T, DMB-T/H, etc. The transmit logic 104may be configured to generate packets containing control information(e.g., signaling/versioning data) as described herein. In oneembodiment, one or more of the digital television channels may beintended for stationary receivers, such as televisions. One or more ofthe digital television channels may also be intended for mobile and/orhandheld (M/H) (referred to collectively herein as “mobile”) devices112B-E. In one embodiment, one or more of the digital televisionchannels may be intended for either stationary receivers or mobiledevices.

The mobile devices 112 may be any of various types of devices, such asportable computer systems (laptops) 112B, wireless telephones 112C(e.g., Blackberrys, iphones, etc.), personal digital assistants 112D,television equipment 112E configured in vehicles, and other types ofportable devices capable of displaying received audiovisual information.

The stationary device(s) 112A may be any of various types of devicesthat are intended to be placed at a fixed location (referred to asstationary or “non-mobile”), such as conventional televisions, e.g.,liquid crystal displays (LCD displays), plasma displays, etc.

The audiovisual devices 112 are configured to receive the packetstransmitted by the transmitter 106, including audiovisual informationand control information. A respective audiovisual device 112 may alsoinclude receiver logic for processing the received audiovisualinformation, as well as a display for presenting video information andone or more speakers for presenting audio information. Thus each of theaudiovisual devices 112 may include television-like capabilities forpresenting received television channels as described herein.

FIG. 2—Transmit Flowchart

FIG. 2 is a flowchart depicting a method for transmitting controlinformation for use with a multimedia stream to an audiovisual device.The method may be performed by a transmission system such as describedabove and shown in FIG. 1, e.g., a system including transmit logic and atransmitter. The multimedia stream may be for reception by mobiledevices; alternatively, the multimedia stream may be for reception bystationary devices, or, both mobile and stationary devices. It should benoted that, according to various embodiments, one or more of the stepsmay be omitted, repeated, or performed in a different order than shownin FIG. 2 and described below.

In 202, first control information according to a first protocol versionmay be generated. The first control information may be for configuringan audiovisual device to present a multimedia stream in a first manner(e.g., according to a first service type). The first control informationmay be a series of commands and data for an audiovisual device tonavigate a tree-based data structure and setting parameter values forone or more leaf nodes of the tree. For example, the first controlinformation may be a series of XCL commands (such as shown and describedwith respect to FIGS. 15-17) for navigating and defining an ATSC M/Htree, (such as shown and described with respect to FIG. 19, 20, or 22).Thus, the first control information might be coded as shown in FIG. 22,or 24, or similarly. Alternatively, the first control information may beany sort of control information for configuring an audiovisual device topresent a multimedia stream. The first control information may begenerated according to a first protocol version. For example, in oneembodiment the first control information might be generated according toa version 1.0 XCL.

In 204, a first data structure may be generated, including informationabout the first control information. The first data structure mayspecify that the first control information is of the first protocolversion. In other words, if the first control information is version 1.0XCL, the first data structure may indicate this. The first datastructure may also (or alternatively) indicate any of various otherkinds of information about the first control information, such aslocation information (such as an offset) for the first controlinformation, and/or a class or type of service of a multimedia streamspecified by the first control information. For example, the firstcontrol information might be for configuring an audiovisual device topresent a multimedia stream in 3-D, or in 2-D. The first data structuremay also include information defining itself, e.g., specifying its size,protocol version, structure, etc.

In one embodiment, the first data structure could be a servicedescriptor, such as described below with respect to FIGS. 12-14. Thus,in this case the data structure would include information definingitself (e.g., protocol version, length, number of columns, length ofcolumns) as well as information about the first control information(type(s) of information, and data for each type of information).Alternatively, the first data structure could be any kind of datastructure.

In 206, a first plurality of packets may be generated. The firstplurality of packets may include a multimedia stream (e.g., audiovisualinformation) specified by the first control information, the firstcontrol information, and the first data structure. The multimedia streammay be received and/or stored prior to generation of the packetsincluding the multimedia stream. The first plurality of packets mayinclude separate subsets of packets, where one subset includes themultimedia stream, while one subset includes the first controlinformation and the first data structure. The subsets may be separate,or may be mixed together (e.g., multiplexed). Alternatively, theinformation may separated in a different way, or may be generated intosimilar packets containing the multimedia stream, the first controlinformation, and the first data structure. The packets may be generatedaccording to any of various formats, e.g., IPv4, IPv6, MPEG-2, orothers.

In 208, the first plurality of packets may be transmitted. The firstplurality of packets may be transmitted by a transmission system, suchas described with respect to FIG. 1 according to various embodiments. Insome embodiments, the first plurality of packets may be provided by aserver, e.g., an internet server. The transmission system may thus be aone-way communication system (e.g., a broadcast system) or a two-waycommunication system (e.g., over the internet, a cellular network, orany two-way communication system).

In 210 second control information according to a second protocol versionmay be generated. The second control information may be for configuringan audiovisual device to present a multimedia stream in a second manner,e.g., according to a second service type. Much like the first controlinformation, the second control information may be a series of commandsand data for navigating a tree-based data structure and settingparameter values for one or more leaf nodes of the tree. For example,the second control information may be a series of XCL commands (such asshown and described with respect to FIGS. 15-17) for navigating anddefining an ATSC M/H tree, (such as shown and described with respect toFIG. 19, 20, or 22). Thus, the second control information might be codedas shown in FIG. 22, or 24, or similarly. Alternatively, the secondcontrol information may be any sort of control information forconfiguring an audiovisual device to present a multimedia stream. Thesecond control information may be generated according to a secondprotocol version, which may be different than the first protocolversion. For example, if the first control information is generatedaccording to a version 1.0 XCL, the second control information might begenerated according to a version 2.0 XCL, or an entirely differentcommand language or form of control information.

The second control information may be for configuring an audiovisualdevice to present the same multimedia stream for which the first controlinformation specifies configuration information for an audiovisualdevice. Alternatively, the second control information may be forconfiguring an audiovisual device to present a different multimediastream (e.g., a different type of multimedia stream, such as amultimedia stream according to a different protocol version than thefirst multimedia stream) than the first control information.

In 212, the first data structure may be modified to include additionalinformation about the second control information. For example, if thefirst data structure is a service descriptor (as described according tovarious embodiments with respect to FIGS. 12-14), the column lengthfield might be modified to indicate an additional item in each column.The information about the second control information might then beincluded as the second item in each column. Thus, the modified firstdata structure might include similar information for the second controlinformation as for the first control information, e.g., protocol versionof the second control information, type or class of service, major/minorchannel number, location information (such as an offset), etc. It shouldbe noted that the first data structure may retain the information aboutthe first control information in addition to being modified to includethe additional information about the second control information. In oneembodiment, the format of the data structure may be modified. Forexample, the first data structure could be a version 1.0 servicedescriptor, while the modified first data structure could be a version2.0 service descriptor. The modified first data structure may includeinformation specifying its format, e.g., may include version informationfor the modified first data structure, and/or size information for themodified first data structure. Alternatively, the data structure mightbe a different kind of data structure than a service descriptor, and maybe modified to include the additional information about the secondcontrol information in any number of ways.

In another embodiment, the first data structure may not be modified, butrather a second data structure may be generated. The second datastructure may be similar to the first data structure, but withinformation about the second control information rather than informationabout the first control information; alternatively, the second datastructure may be a different kind of data structure. For example, thesecond data structure may be a service descriptor of a differentprotocol version, or another kind of data structure altogether. Such asecond data structure might still include similar information as thefirst data structure but for the second control information, e.g.,protocol version information for the second control information,location information (such as an offset), etc.; alternatively, thesecond data structure might include any of various different kinds ofinformation about the second control information.

In one embodiment, the information in the data structure(s) about thefirst and second control information may be usable by a receiver (e.g.,a receiving audiovisual device) to determine what control information itcan or should use and what control information it can or should ignore.For example, the first data structure might identify the first controlinformation as being of a first protocol version, and provide a locationof the first control information in the plurality of packets; thus, ifan audiovisual device is not configured to parse the first protocolversion of the first control information, the audiovisual device may beable to use the information in the first data structure to ignore thefirst control information. Similarly, if there are a number of sets orgroups of control information, a data structure such as a servicedescriptor may be used by an audiovisual device to determine more thanone group of control information whose protocol versions it is notconfigured to understand, and the audiovisual device may thus be able touse that data structure to ignore those groups of control informationwhose protocol versions it is not configured to understand.

In 214, a second plurality of packets may be generated, including themodified first data structure, the first control information, the secondcontrol information, a multimedia stream specified by the first controlinformation, and a multimedia stream specified by the second controlinformation. Each multimedia stream may be received and/or stored priorto generation of the packets including the multimedia stream. Themultimedia stream specified by the second control information may be thesame multimedia stream as the multimedia stream specified by the firstcontrol information; alternatively, they may be two different streams.For example, the multimedia stream specified by the first controlinformation may be generated according to a first protocol version,while the multimedia stream specified by the second control informationmay be generated according to a second protocol version.

The second plurality of packets might also include other information,such as additional multimedia streams, additional control information(e.g., for the additional multimedia streams), and/or additional datastructures (e.g., providing information such as location and protocolversion information about the additional control information). It shouldalso be noted that the first data structure (or the second datastructure) might also include additional information about additionalcontrol information, for example, a single data structure could includeinformation about a plurality of sets or groups of control information,where each set or group of control information could be of a differentprotocol version, and/or have one or more other defining characteristicsthat could be used to index that group of control information. In oneembodiment, the second plurality of packets may include informationspecifying a number of data structures which are included in the secondplurality of packets, for example, if there are two or more datastructures.

The second plurality of packets may include separate subsets of packets,where there is one subset for each multimedia stream, while one subsetincludes the first control information and the first data structure. Thesubsets may be separate, or may be mixed together (e.g., multiplexed).Alternatively, the information may separated in a different way, or allthe packets generated may similarly contain portions of each of themultimedia stream, the first control information, and the first datastructure. The packets may be generated according to any of variousformats, e.g., IPv4, IPv6, MPEG-2, or others.

In 216, the second plurality of packets may be transmitted. The secondplurality of packets may be transmitted by a transmission system, suchas described with respect to FIG. 1 according to various embodiments. Insome embodiments, the “transmitting” the first plurality of packets mayinclude providing of the first plurality of packets by a server, e.g.,an internet server. The transmission system may thus be a one-waycommunication system (e.g., a broadcast system) or a two-waycommunication system (e.g., over the internet, a cellular network, orany two-way communication system).

In some embodiments, additional pluralities of packets (e.g., a third, afourth, etc) may be generated and transmitted, including additionalcontrol information, additional or modified data structures, additionalmultimedia streams, etc., as new protocol versions, services, etc., aredeveloped and/or released.

The method described above for transmitting control information for usewith a multimedia stream to an audiovisual device may be performed by asystem for transmitting control information for a multimedia stream toan audiovisual device according to various embodiments. For example, thesystem might include an input for receiving one or more multimediastreams, transmit logic for generating and/or modifying controlinformation, data structures, and/or packets, and/or a transmitter fortransmitting packets.

FIG. 3—Receive Flowchart

FIG. 3 is a flowchart depicting a method for an audiovisual devicereceiving control information for a multimedia stream. The method may beperformed by any kind of audiovisual device. For example, the method maybe performed by a mobile device such as described above and shown inFIG. 1, e.g., portable computer systems (laptops), wireless telephones(e.g., Blackberrys, iphones, etc.), personal digital assistants,television equipment configured in vehicles, and other types of portabledevices capable of displaying received audiovisual information.Alternatively, in some embodiments, the method may be performed by astationary device, such as also shown in FIG. 1 and described above,e.g., a conventional television, such as liquid crystal display (LCDdisplay) television, a plasma display television, etc. It should benoted that, according to various embodiments, one or more of the stepsmay be omitted, repeated, or performed in a different order than shownin FIG. 3 and described below.

In 302, a first plurality of packets may be received. The firstplurality of packets may include a first multimedia stream, firstcontrol information, second control information, and a first datastructure. The first data structure may include location and protocolversion information for the first and second control information. Thefirst and second control information may have been generated accordingto different protocol versions. Each set of control information may befor the first multimedia stream, or may be for different multimediastreams. For example, the first plurality of packets may include one ormore additional multimedia streams. In various embodiments, the datastructure may be a service descriptor. The first and/or the secondcontrol information may have been generated according to embodiments ofXCL, e.g., different protocol versions of XCL. If there are multiplemultimedia streams, some may be of different protocol versions thanothers.

In 304, the first data structure may be analyzed to determine thelocation and protocol version information for the first and secondcontrol information. The audiovisual device may be able to use the firstdata structure (e.g., the location and protocol version information) todetermine which control information it can or should use to configureitself, and conversely, which control information it may be able toignore. Thus, the audiovisual device may not be configured to understandthe second protocol version of the second control information, and maytherefore use the location information of the control information toignore the second control information.

In 306, the audiovisual device may be configured according to the firstcontrol information. The audiovisual device may be configured tounderstand the first protocol version. Thus, the audiovisual device maybe able to use the information in the data structure to determine thelocation of the first control information and parse the first controlinformation. Thus, the audiovisual device may use be able to configureitself according to the first control information. Configuring theaudiovisual device may enable the audiovisual device to present thefirst multimedia stream.

In 308, the first multimedia stream may be presented. Presenting thefirst multimedia stream may include presenting video information on adisplay and/or presenting audio information on one or more speakers

FIG. 4—Architecture with In-Line Signaling

FIG. 4 illustrates a system architecture with in-line signaling, ascommonly used in the art. It is customary in communication systems tohave the signaling information processed by many of the system blocksthat are involved in the processing of the service, thus those blocksare restricted in their ability to be changed without breaking backwardscompatibility. For example, FLUTE is a file management protocol. It isused to manage file based content, including the signaling in manywireless standards like OMA BCAST and DVB-H. The signaling informationis passed from the transmitter to the target receiver in FLUTE fileformat. This means that the FLUTE functionality cannot be changed in anon backwards compatible way, and it cannot be replaced. If the targetreceiver has a version 1.0 FLUTE functionality, and the transmittersends the signaling information in a FLUTE 2.0 version format (assumednot to be backwards compatible), the receiver will drop the packet atthe FLUTE functionality and the signaling functionality will never seeany indication the information was ever received. For this reason, itmay make more sense to include signal processing at a lower level, e.g.,as in the system architectures shown in and described with respect toFIGS. 8 and 9.

FIG. 5—Tree Based Data Structure

As mentioned above, one aspect of an extensible signaling/versioningframework is a structure for the signaling/versioning information whichallows for insertion of new or modified signaling/versioning data insuch a way that a receiver (e.g., an audiovisual device) which doesn'tsupport the new/modified signaling/versioning data can skip or ignoreit.

Current signaling schemes typically rely on static tables to communicatesystem parameters and other system configuration information. Such atable might have a bit defined structure for communicating parametersincluding a mixture of raw binary values and enumerated types. A fewbits may be reserved for future use, but there is typically no way toextend or change such a table without breaking backward compatibility.An exemplary form for such a table might be as follows:

Syntax # of bits List Header ( ){  Parameter 1 3  Parameter 2 1 Parameter 3 16   .   .   .  Parameter N 4 }

Such tables have been used in the ATSC M/H system for transmitting aTransmission Parameter Channel (TPC), a Fast Information Channel (FIC),and a Service Map Table (SMT). The TPC provides the configuration of andrelative location in the M/H communication protocol. The FIC providesbinding information between an M/H service (e.g., virtual channel) andan M/H ensemble (M/H data structure). The SMT provides bindinginformation between an M/H service (e.g., virtual channel) and the IPdatagrams.

These tables may be a relatively bit efficient format for signalinginformation, but leave little room for modifying or extending theformat. As shown, this scheme does not support protocol versioning; theversioning bits included in the tables are used to signal if there hasbeen a change to the data signaled, not a change to the signaling orother functionality related to the protocol itself.

One option to provide the desired extensibility is simply to includeversioning information for the tables (or portions of the tables) withinthe tables.

Another alternative to the use of static data tables is the use of treebased data structures. FIG. 5 illustrates an exemplary tree based datastructure. A data tree may include a root node, one or more ‘sub-nodes’(or ‘branches’), and one or more leaves for each of the branches. A treemay also have additional layers, e.g., ‘sub-sub nodes’ (or ‘twigs’), asdesired.

A tree based data structure allows for each node and/or leaf to beindividually defined in terms of both its versioning information and itsactual value or values (e.g., parameter values). A tree based datastructure also allows nodes to be added without breaking backwardscompatibility. Thus, tree based data structures may providesignificantly more extensibility and forward compatibility than staticdata tables. Communication using tree based data structures canpotentially incur significant additional overhead, e.g., may be less bitefficient than a static table, depending on the command set used withthe tree. However, with a bit efficient command set, such as describedbelow with respect to FIGS. 15-17, this problem may be substantiallymitigated, e.g., given a bit efficient command set, communicating usinga tree based data structure may be comparable in bit efficiency to usinga data table.

FIGS. 6 and 7—ATSC M/H Functional Blocks

FIG. 6 illustrates an exemplary partitioning of the ATSC M/H system intoa set of functional blocks for versioning. The term versioning is usedhere to specify a methodology for assigning revision numbers to updatesin functionality and for communicating the revision numbers in a waythat supports robust communication with legacy and current versionreceivers simultaneously. The methodology can then be used to extendservices from a given transmitter to legacy and current generationreceivers simultaneously.

As shown in FIG. 6, the functional blocks may be divided into multiplelayers of a protocol stack. Thus, there may be a presentation layer, amanagement layer, and a physical layer in one embodiment. Each protocollayer may include a number of elements; e.g., as shown, the presentationlayer may include a service guide, graphic elements, captioning, audiocodecs, and video codecs. Various other protocol stacks, includingdifferent protocol layers and/or different elements within the protocollayers, are also envisioned. For example, it should be noted that someembodiments of the invention provide for modifying or replacing areceiver's protocol stack. Thus, in one embodiment, a new protocolversion could specify addition, replacement, retirement, orrearrangement of one or more elements of a protocol stack. In oneembodiment, a tree based structure, such as shown in FIG. 7, may be usedto navigate and configure a device according to the revised protocolstack (e.g., if the new protocol version is supported) or according tothe previous protocol stack (e.g., if the new protocol version is notsupported).

FIG. 7 illustrates a treed version of part of the ATSC M/H protocolstack described in FIG. 6. Each protocol element may be enumerated as aleaf of a respective node (e.g., protocol layer) of the tree (e.g.,protocol stack). Thus, each node and element can be versioned separately

FIGS. 8 and 9—Exemplary Architectures

FIGS. 8 and 9 illustrate exemplary receiver system architectures inwhich the signaling and/or versioning processing functionality is lowerin the system and/or separated from the processing of the services. Thismay mitigate the problems discussed with respect to FIG. 4. FIGS. 8 and9 are exemplary only, thus it should be noted that other receiverarchitectures are also possible.

FIG. 10—Packet Format

FIG. 10 illustrates a packet format that may be used to communicatesignaling/versioning data (or simply ‘control information’) for amultimedia stream according to one embodiment. As shown, packets mayinclude fields for a header, a length, a fragment number, a servicedescriptor, commands/modifiers, data, and a CRC 16. Locations for theheader, length, fragment number, service descriptor, and CRC 16 may befixed. The content of the service descriptor may be configurable. Thecontrol stream itself may include a concatenated series ofcommand/modifier/data nibbles. Although FIG. 10 shows one exemplarypacket format, any number of other packet formats are also possible,including packets with different sized fields, additional fields, fewerfields, similar but modified fields, and/or any number of otherdifferences. Definitions and further description of the fields of thisexemplary packet format are provided below with respect to FIG. 11.

FIG. 11—Table of Control Packet Fields

FIG. 11 is a table defining the fields of a control packet according toone embodiment. As described above with respect to FIG. 10, in oneembodiment the fields may include a header, a length, a fragment number,a service descriptor, commands/modifiers, data, and a CRC 16.

The header may be 4 bits (1 nibble) in length. The header may includethe version number of the control packet. In other words, this providesa means to signal versioning information for the signaling methoditself. Thus, while the fields described below might define the fieldsin a version 1.0 control packet, a future version might define thefields differently, or might include different fields; by signaling theversion of the signaling method, a receiver may be able to cope withfuture updates to the signaling method (e.g., by updating its softwareto accommodate the new version, or ignoring the new version if it isincompatible).

The length field may be 8 bits (2 nibbles) in length. The length fieldgives the length of the packet body (as defined as the fields startingafter the packet length field and ending with the last byte of thepacket) in bytes. A receiver which recognizes by the packet header thatit cannot support the packet, may at least be able to parse this fieldto determine how big the packet is, and thus, how far it should skip tobegin attempting to parse the next packet in the control stream.

The fragment number field may be 4 bits (1 nibble) in length. Thefragment number field gives the number of fragments in the packet,starting at the value 0001 (e.g., instead of starting at the value0000). The value 0000 may be a special value indicating no fragmentationis used.

The service descriptor may be a variable number of bits. The servicedescriptor field maps the versioned signaling stream to services, asreferenced by service identifier (IP address), major channel number,etc. The service descriptor, or service discovery table, may be used toindex the control information, e.g., such that a receiver may determinewhich portion(s) in the control information it can and cannot support,and/or which portion of the control information may be relevant to aparticular service to which the receiver is attempting to present.Further details on embodiments of the service descriptor are given belowwith respect to FIGS. 12-14.

The command, modifier, and data fields make up the control informationof a control packet. In other words, the commands, modifiers, and datain these fields may be a means for navigating the structure (e.g., atree structure) of the signaling/versioning information for configuringan audiovisual device to present an accompanying multimedia stream.According to one embodiment, each command, modifier, or data field maybe 4 bits (1 nibble), or may be extended indefinitely in nibbleincrements. Thus, the means may be extensible. Further details onembodiments of a command set, referred to herein as an “extensiblecontrol language” (“XCL”) are given below with respect to FIGS. 15-17.

The CRC 16 is a 16 bit cyclic redundancy check, calculated over theentire length of the packet, which may be used for errordetection/correction purposes.

FIG. 12—Service Descriptor Format

FIG. 12 illustrates a format of the service descriptor field in an XCLpacket according to one embodiment. The service descriptor may beformatted as a table with configurable column types. The servicedescriptor field may include a subfield for each of: service descriptortype, service descriptor length, number of columns, and column length.The service descriptor field may also include column type and datasubfields for each column in the table.

FIG. 13—Table of Service Descriptor Fields

FIG. 13 is a table defining the subfields that make up the servicedescriptor field of an XCL packet according to one embodiment. Asmentioned above with respect to FIG. 12, there may be subfields forservice descriptor type, service descriptor length, number of columns,column length, column type, and data. Each subfield field may be 4 bits(1 nibble) in length, or may be extended indefinitely in nibbleincremements.

The service descriptor type may be used to version the servicedescriptor. In other words, the service descriptor may be versionedseparately from (or in addition to) the versioning of the control packetas a whole. Thus, while the fields described below might define thesubfields for one version of a service descriptor, a future versionmight define the fields below differently, or might include differentfields; by signaling the version as the header, a receiver may be ableto determine whether it is able to parse the service descriptor beforeactually attempting to parse the body of the service descriptor. Thus,if the receiver is not configured to parse a particular servicedescriptor, it may update its software to accommodate the new version,or ignore the new version if it is incapable of accommodating the newversion.

The service descriptor length subfield specifies the length of theservice descriptor field in nibbles. A receiver which recognizes by theservice descriptor type that it cannot support the service descriptor,may at least be able to parse this field to determine how big theservice descriptor is, and thus, how far it should skip to beginattempting to parse the next piece of information (such as anotherservice descriptor which it can parse) in the control stream.

The number of columns (or “NumColumns”) subfield specifies the number ofcolumns in the table, which also effectively specifies the number ofcolumn type and data subfields to follow. The column length subfieldspecifies the number of items in each column. All columns may be thesame length. By including fields specifying the number of columns andthe length of the columns, the service descriptor is essentially able todefine itself. Thus, the service descriptor may be a very flexible datastructure by design, potentially allowing for a significant amount ofmodification and/or variation in the format and thus the informationprovided without requiring a new protocol version.

The column type subfield specifies the type of information in thefollowing data field. A variety of possible types of information may beenumerated for a given service descriptor version; example types mightbe Version Number, Stream ID, IP Address, Major Channel Number, or MinorChannel Number.

A data subfield specifies values for each item of a column. The numberof items, as mentioned above, is specified by the column lengthsubfield. The length of each item may be specified (e.g., defined) aspart of the column type. For example, if the column type is IPv4, thenan item may be 32 bits.

FIG. 14—Exemplary Service Descriptor Field

FIG. 14 is a table showing an exemplary service descriptor field, brokendown by subfield. In this example, the value of the service descriptortype may be ‘0000’, indicating a base version. The service descriptorlength may be ‘1011’, indicating that there are 11 (1011 in binary)nibbles in the service descriptor. The number of columns may be ‘0011’,indicating that there are 3 (0011 in binary) columns. The column lengthmay be ‘0001’, indicating that each column contains 1 item. Three columntype subfields, each followed by a 1-item data subfield may follow. Inthis example, the column types are version number (enumerated as‘0000’), major channel number (enumerated as ‘0001’), and an offsetvector (0010). In other words, this service descriptor specifies thatthe control information for major channel ‘0001’, which is of baseversion ‘0000’, is located at the offset vector 0010.

A single service descriptor may be used to index multiple portions ofthe control information. For example, a service descriptor might pointto a first group of commands, which might be for a particular serviceand/or of a particular protocol version, and also might point to asecond group of commands, which might be for a different service and/ora different protocol version. Thus, if there are several groups ofcommands, but only one group has a base version of 1.0, and all othergroups have higher base versions, a legacy receiver which can onlysupport base version 1.0 may parse the service descriptor, and therebydetermine that it can support the group with base version 1.0 but cannotsupport (and can therefore ignore or skip) the groups with higher baseversions.

Multiple service descriptors may also or alternatively be used in someembodiments. For example, a service descriptor of a new protocol versionmay be used alongside a service descriptor of an older protocol version,to enable a legacy device to determine the services it can receive, andto also enable a current device to use the service descriptor with thenew protocol version to determine the services it can receive. In someembodiments, a current device may be able to use more than one (e.g., inthis example, both the newer and the older) service descriptor todetermine services it can receive.

FIG. 15—Command Series Format

FIG. 15 is a table illustrating one possible format for a series ofcommands/data. As shown, there may be fields for a command to beperformed, a length of the command payload in bytes (e.g., to allow anunknown command to be skipped by a legacy receiver), one or morenavigational fields specifying a leaf or node where the parameter(s) tobe specified are located, and the actual parameter(s) to be set.

FIG. 16—XCL Command Set

As noted above, following the service descriptor field in a controlpacket, there may be a concatenated series of command/modifier/datanibbles. FIG. 16 is a table defining one possible set of commands forcommunicating and navigating a tree based data structure. As notedabove, this embodiment of a command language is referred to herein as“XCL”.

An XCL language is a flexible, extensible method of structuring data,and more specifically a method of encoding tree based information in avery bit efficient way. The method may include of a set of commands, tobe followed by a variable number of fields of data, used to communicatenodes in a tree and the corresponding parameter values located at each.The method is analogous to sectioning a table of data into groups ofparameters, and encapsulating each group in a header that specifies thelocation of the parameter set in the table. Indeed, that would beanother possible embodiment. Representation of parameters in thisstructured format supports the addition or subtraction of parameter setsin a forward compatible way. Legacy receivers that encounterunrecognized nodes, are able to skip over then and continue to parsedata they support.

The language may also include a set of modifiers, which are parametersthat can be applied across sections of the tree, enabling a short handway of communicating that numerous nodes have values of a similarnature, thus avoiding the need to express the path to each node and thevalue of each modifying parameter separately. This capability iscomparable to a header that encapsulates multiple groups of parameterswith headers. Example uses of this capability would include a modifierused to specify that all the parameters on a section of the tree areATSC M/H version 1.0 compatible, or that the parameters on one sectionof the tree are the same as those on another section of the tree withminimal differences. When the modifiers are used to specify the latteruse, only the location of the comparable node and the differences may bespecified.

In one embodiment, the command and data fields may be organized onnibble, byte, or any other fixed boundaries. Taking nibble boundaries asan exemplary embodiment, one bit in each nibble may be used to mark thenibble as either a command or data. For example, in one embodiment, themost significant bit (MSB) may be used. Thus, in this embodiment, if theMSB is a ‘0’, that marks a command, while a ‘1’ as MSB marks data. This,or any similar convention for marking commands and data nibbles as such,may be useful in enabling a receiver to parse the command and datainformation, e.g., a receiver may be able to determine that a series ofnibbles each beginning with ‘0’ are commands, and one or more nibblesfollowing those commands which each begin with ‘1’ are the dataspecified by those commands. Thus, a receiver may parse a series ofcommands (e.g., navigating to a node or leaf in the tree), followed bydata (e.g., parameters for that node or leaf), and may recognize wherethe data ends and the next series of commands begins as the next nibblewith a ‘0’ as MSB. In some embodiments, this may save the overhead ofusing a dedicated length field to indicate to a receiver how long eachcommand sequence is. In some embodiments, length fields may still beused with some or all of the commands. The three least significant bits(LSBs) of a command or a data field may indicate what the enumeratedcommand or data value for a field is.

If necessary, a command or data field may be extended by setting thethree LSBs to ‘111’, or in other embodiments, to any other valuespecified to denote field extension. In this way, the command set may beextended indefinitely without interfering with a legacy receiver'sability to parse the command stream. That is, even if a receiver doesn'trecognize the command in the extended field, it may still be able torecognize that the field was extended, and skip to the next field.

FIG. 16 includes brief descriptions of each command according to oneembodiment. A more detailed description of each of these possiblecommands is given below.

The Node (or Group) pointer points to a parameter (or group ofparameters) in a hierarchical tree structure. The node command combinesnavigation with parameter specification. The node command includes avariable number of data fields, some to specify the nodes traversed, oneto specify a leaf location and a final one to specify theparameter/function set. When using the node command, the current nodelocation is set to the node just above the leaf referenced for settingthe parameter. For example, if a receiver is at the default node 0, andwe desire to set the leaf at location 0.1.0.0 to value_(—)1, the commandwould be 0001 (command), 1001(data), 1000(data), 1000(data),value_(—)1(data). The last data field is the parameter value. The nextto last data field is the leaf location, and the current node is justabove 0.1.0.

The Descend command specifies a relative path (downward) to a parameterlocation below the current one in the hierarchical tree structure. Thiscommand is used to navigate to a new node in the tree. The Descendcommand includes a variable number of data fields, each one specifying anode to traverse. The total number of nodes to traverse may bedetermined by how many data fields are following the Descend command,prior to the next command nibble. For example, if a receiver iscurrently pointing to the default node 0, and it is desired to point tonode 0.1.1, the descend command would be 0100 (command), 1001 (data),1001 (data). The command and data values are shown with their MSBs setper their type (e.g., command or data). The receiver may track thecurrent node location and all navigation commands may thus be configuredwith respect to the current node. Alternatively, each navigation commandmay begin from a root node; in this case, the ascend command describedbelow may be unnecessary.

The Ascend command specifies a number of levels to traverse (upward) inthe hierarchical tree structure. The ascend command reverses the descentcommand by the specified number of levels. Since each child node in thetree only has one parent, no further specification may be needed.

The Modifier command specifies a value to apply to all parameters belowthe current location in the hierarchical structure. The Modifier commandis a special command for specifying parameters on sections of the treeinstead of at just one location. The first step to using a modifiercommand is to navigate to the desired node location in the tree usingthe Descend command. The Modifier is then applied by adding the Modifiercommand and associated fields after the Descend command. Modifiers canbe inserted anywhere in the XCL commands, but may be most efficient whenthey are placed so that the navigation to specify a parameter(s) and thenavigation to specify a Modifier are combined. Modifiers may also bemost efficient when the treed data is arranged in such a way thatparameters that can be set with common values are grouped together underthe same node.

While this set of commands is one possible embodiment of an XCL, anynumber of other variations, such as the command set shown in FIG. 24,are also possible.

FIG. 17—XCL Command Set Modifiers

As described above, a Modifier command specifies that the data to followincludes a particular modifier and a one or more corresponding modifiervalues, which apply to the all nodes of the tree below the current node.FIG. 17 is a table enumerating and defining each of these modifiersaccording to one embodiment. Further explanation of each of thesepossible modifiers is given below.

A Subversion (or protocol generation) modifier specifies the protocolsub generation of the parameters specified on the nodes below thecurrent one. This is the generation of a particular elementarysubsystem. The protocol generation of the service as a whole may bespecified by the root location of the tree navigated.

An Exception modifier specifies that data parameters on the nodes belowthe current one are exceptions to the most recent Modifier specified.

An Optional modifier specifies that any data parameters on the nodesbelow the current one are optional extensions. All parameters specifiedmay be required unless noted otherwise with a Modifier command followedby an ‘optional’ data field applied to the node the parameter(s) resideon. This modifier may be useful to include optional components in aservice, e.g., which may be of a different base protocol version thanthe service as a whole. This would allow legacy devices to use theservice without the optional components, while newer receivers could usethe (e.g., service enhancing) optional components.

A Replicate modifier specifies a hierarchical node to replicate at thislocation. That is, all parameters from the specified node may be copiedto the current location.

One or more values may be reserved for future use, as well as a valuefor extending the modifier field, e.g., essentially allowing moremodifiers to be defined even if all of the reserved values are used. Inthe embodiment shown, the ‘extend field’ value for a modifier is ‘1111’.

While FIG. 17 shows one possible set of command modifiers, any number ofembodiments are possible; for example, an alternate embodiment is shownin FIG. 25.

FIG. 18—ATSC M/H Tree

FIG. 18 illustrates a portion of a tree based version of an ATSC M/Hprotocol stack according to one embodiment. Using the commands describedabove, such a tree may be navigated, and versioning and parameterinformation may be provided, in a bit-efficient way.

FIG. 19—ATSC M/H Tree

FIG. 19 illustrates another representation of an ATSC M/H tree. Notethat the tree includes leaves for all of the System Configurationsignaling ‘tables’, e.g., the FIC, SMT, CIT, STT, SLT, and GAT, suchthat these tables (or trees) may also be versioned. In some embodiments,such a tree may be arranged specifically in a manner as to takeadvantage of the command language (e.g., XCL) which will be used toencode it. For example, table data can be structured optimally to takefull advantage of the XCL capabilities by minimizing the number of nodesneeded, and maximizing the number of leaves at each node. This mayminimize the navigation overhead. Depending on the command languageused, certain rules may also apply to the construction of such a tree.For example, for the XCL embodiment described above, the following rulesmay apply:

1) Nodes are for navigation only and do not contain parameters (data).

2) A new node can only be added to another node (not to a leaf)

3) Nodes are placed in locations of the tree where future parameters mayneed to be added.

4) Parameters are located at leaves. Leaves are locations at thetermination points of nodes.

These rules are exemplary only, and thus it will be noted that,depending on the command set used, a different set of rules may beessential or helpful in improving the efficiency of the signalingframework.

In some embodiments, a given tree (e.g., an FIC tree) may typically bedefined once per protocol generation. Subsequent additions andsubtractions to the table may be implemented as amendments to theoriginal tree, maintaining the order, so that the location in the treecommunicates information (e.g., trees descending from node 0 are alwaysa first protocol generation service.)

When constructing the signaling structure for the data, the extent towhich the data is treed controls the flexibility and extensibility ofthe data. For maximum flexibility, each parameter can be located on aseparate leaf (e.g., fully resolving a tree). Alternatively, a moreefficient signaling structure can be achieved through groupingparameters at each leaf (e.g., partially resolving a tree).

FIG. 20—FIC Tree

FIG. 20 illustrates a partially resolved tree representation of the FIC,including hypothetical nodes for future extension of the tree at eachnode. This tree could be used in combination with the tree of FIG. 19(e.g., the FIC root node is node 0.8.0 in the system configuration treeshown in FIG. 19). For example, the tree as shown but without the“Future Field(s)” could be the version 1.0 FIC tree. A version 1.1 FICtree might include one or more additional fields where one or more ofthe “Future Field(s)” are shown. In this case, the additional nodesand/or leaves might be version 1.1, while the original nodes and leavesmight remain 1.0. A version 2.0 FIC tree could have an entirelydifferent structure, e.g., be rearranged, or include different fields.

FIG. 21—Exemplary Coding of a FIC Tree

FIG. 21 shows an exemplary coding of a portion of the FIC table shown inFIG. 20 according to the XCL embodiment described above with respect toFIGS. 15-17. FIG. 21 just shows the command/data portion of a controlpacket (e.g., the control information); it should be noted that in someembodiments this may be only a portion of a control packet that alsoincludes other fields (e.g., packet header, length, etc., such asdescribed in FIG. 10)

FIG. 22—SMT Tree

FIG. 22 illustrates a partially resolved tree representation of the SMT,including hypothetical nodes for future extension of the tree at eachnode. This tree could be used in combination with the tree of FIG. 19(e.g., the SMT root node is node 0.5.0 in the system configuration treeshown in FIG. 19). For example, the tree as shown but without the“Future Field(s)” could be the version 1.0 SMT tree. A version 1.1 SMTtree might include one or more additional fields where one or more ofthe “Future Field(s)” are shown. In this case, the additional nodesand/or leaves might be version 1.1, while the original nodes and leavesmight remain 1.0. A version 2.0 SMT tree could have an entirelydifferent structure, e.g., be rearranged, or include different fields.

FIG. 23—Exemplary Coding of an SMT Tree

FIG. 23 shows an exemplary coding of a portion of the SMT table shown inFIG. 22 according to the XCL embodiment described above with respect toFIGS. 15-17. The code shown in FIG. 23 may be part of a larger controlpacket, as indicated by the ‘header’, ‘length’, ‘fragment number’, and‘service descriptor’ fields shown at the top of FIG. 23.

FIGS. 24 and 25—Alternate Embodiments of XCL Commands

FIGS. 24 and 25 show alternate embodiments of the XCL commands andcommand modifiers respectively. Thus, while the XCL shown and describedwith respect to FIGS. 15-17 may be one embodiment of a command set forencoding tree based information, the set shown in FIGS. 24 and 25, orany such command set, may alternatively be used as desired as aflexible, extensible method of encoding tree based information in a verybit efficient way

FIGS. 26-28—Alternate Embodiments of FIC and SMT Data Trees

FIGS. 26-28 show several alternate embodiments of data trees. FIG. 26shows a fully resolved tree representation of the FIC according to oneembodiment. Fully resolving a data tree maximizes flexibility andextensibility of the tree, and redundancy can still be effectivelyexploited with the ‘replicate’ command modifier to minimize theadditional navigation overhead incurred by fully resolving the tree.

Alternatively, instead of fully resolving a tree, it is also possible topartially resolve a tree, as shown in FIG. 27. In this way, groups ofleaves which are similar or likely to be modified at the same time or inthe same way may be used to reduce the overhead involved in navigatingthe tree. However, this limits the flexibility and extensibility of thetree, and the groupings must be well designed to anticipate which leavesare likely to change at the same time and in the same ways.

FIG. 28 shows an alternate embodiment of a partially resolved SMT datatree.

Although the embodiments above have been described in considerabledetail, numerous variations and modifications will become apparent tothose skilled in the art once the above disclosure is fully appreciated.It is intended that the following claims be interpreted to embrace allsuch variations and modifications.

We claim:
 1. A method for generating control information for use intransmission with multimedia content to an audiovisual device, themethod comprising: generating first control information, wherein thefirst control information is for configuring the audiovisual device topresent the multimedia content; wherein the control information isorganized according to a tree data structure having a plurality ofnodes, wherein at least some of the nodes are leaf nodes, wherein theleaf nodes store data values for configuring the audiovisual device;wherein the control information comprises a plurality of commands,wherein at least a subset of the commands are executable by theaudiovisual device to navigate the nodes of the tree structure to locatethe data values stored at the leaf nodes; wherein at least a subset ofthe commands have associated data fields, wherein each of the pluralityof commands comprises a plurality of bit portions of a uniform length,wherein each of the data fields comprises a plurality of bit portionshaving uniform length; wherein a designated bit of the bit portions ofthe commands has a first value indicating that the bit portion is acommand; wherein a designated bit of the bit portions of the data fieldshas a second value indicating that the bit portion is a data field,wherein the second value is different than the first value; storing thefirst control information for transmission to the audiovisual device. 2.The method of claim 1, wherein at least one of the commands is amodifier command including a length value and which specifies aparameter value applied to all data values within a length distance fromthe modifier command specified by the length value.
 3. The method ofclaim 2, wherein the modifier command specifies that all data valueswithin the length distance from the modifier command specified by thelength value are optional data values.
 4. The method of claim 2, whereinthe modifier command specifies that all data values within the lengthdistance from the modifier command specified by the length value aremandatory data values.
 5. The method of claim 1, wherein at least asubset of the commands are executable to navigate the tree structurerelative to a current position in the tree structure.
 6. The method ofclaim 1, wherein at least a subset of the commands are executable tonavigate the tree structure relative to a root node of the treestructure.
 7. The method of claim 1, wherein at least one of thecommands is a modifier command that specifies a parameter value for allleaf nodes below a current node position in the tree data structure. 8.The method of claim 7, wherein the modifier command specifies that alldata values below the current node position in the tree data structureare one of: optional; or mandatory.
 9. The method of claim 1, furthercomprising: transmitting the first control information and themultimedia content to the audiovisual device.
 10. A system, comprising:a processor; and a computer accessible memory medium comprising programinstructions executable by the processor to: generate first controlinformation, wherein the first control information is for configuring anaudiovisual device to present the multimedia content; wherein thecontrol information is organized according to a tree data structurehaving a plurality of nodes, wherein at least some of the nodes are leafnodes, wherein the leaf nodes store data values for configuring theaudiovisual device; wherein the control information comprises aplurality of commands, wherein at least a subset of the commands areexecutable by the audiovisual device to navigate the nodes of the treestructure to locate the data values stored at the leaf nodes; wherein atleast a subset of the commands have associated data fields, wherein eachof the plurality of commands comprises a plurality of bit portions of auniform length, wherein each of the data fields comprises a plurality ofbit portions having uniform length; wherein a designated bit of the bitportions of the commands has a first value indicating that the bitportion is a command; wherein a designated bit of the bit portions ofthe data fields has a second value indicating that the bit portion is adata field, wherein the second value is different than the first value;and store the first control information for transmission to theaudiovisual device.
 11. The system of claim 10, wherein at least one ofthe commands is a modifier command including a length value and whichspecifies a parameter value applied to all data values within a lengthdistance from the modifier command specified by the length value. 12.The system of claim 11, wherein the modifier command specifies that alldata values within the length distance from the modifier commandspecified by the length value are one of: mandatory; or optional. 13.The system of claim 10, wherein at least one of the commands is amodifier command that specifies a parameter value for all leaf nodesbelow a current node position in the tree data structure.
 14. The systemof claim 13, wherein the modifier command specifies that all data valuesbelow the current node position in the tree data structure are one of:optional; or mandatory.
 15. The system of claim 10, wherein the systemfurther comprises an antenna, wherein the program instructions arefurther executable by the processor to: transmit the first controlinformation and the multimedia content to the audiovisual device usingthe antenna.
 16. A method performed by an audiovisual device forreceiving and presenting multimedia content, the method comprising:receiving the multimedia content; receiving first control information,wherein the first control information is for configuring the audiovisualdevice to present the multimedia content; wherein the controlinformation is organized according to a tree data structure having aplurality of nodes, wherein at least some of the nodes are leaf nodes,wherein the leaf nodes store data values for configuring the audiovisualdevice; wherein the control information comprises a plurality ofcommands, wherein at least a subset of the commands are executable bythe audiovisual device to navigate the nodes of the tree structure tolocate the data values stored at the leaf nodes; wherein at least asubset of the commands have associated data fields, wherein each of theplurality of commands comprises a plurality of bit portions of a uniformlength, wherein each of the data fields comprises a plurality of bitportions having uniform length; wherein a designated bit of the bitportions of the commands has a first value indicating that the bitportion is a command; wherein a designated bit of the bit portions ofthe data fields has a second value indicating that the bit portion is adata field, wherein the second value is different than the first value;configuring the audiovisual device to present the multimedia contentaccording to the first control information; and presenting themultimedia content.
 17. The method of claim 16, wherein at least one ofthe commands is a modifier command including a length value and whichspecifies a parameter value applied to all data values within a lengthdistance from the modifier command specified by the length value. 18.The method of claim 17, wherein the modifier command specifies that alldata values within the length distance from the modifier commandspecified by the length value are one of: mandatory; or optional. 19.The method of claim 16, wherein at least one of the commands is amodifier command that specifies a parameter value for all leaf nodesbelow a current node position in the tree data structure.
 20. The methodof claim 19, wherein the modifier command specifies that all data valuesbelow the current node position in the tree data structure are one of:optional; or mandatory.
 21. An audiovisual device configured towirelessly receive and present multimedia content, the audiovisualdevice comprising: an antenna; and receiver logic coupled to the antennaand configured to: receive the multimedia content, wherein themultimedia content is received in a wireless manner using the antenna;receive first control information, wherein the first control informationis for configuring the audiovisual device to present the multimediacontent; wherein the first control information is received in a wirelessmanner using the antenna; wherein the control information is organizedaccording to a tree data structure having a plurality of nodes, whereinat least some of the nodes are leaf nodes, wherein the leaf nodes storedata values for configuring the audiovisual device; wherein the controlinformation comprises a plurality of commands, wherein at least a subsetof the commands are executable by the audiovisual device to navigate thenodes of the tree structure to locate the data values stored at the leafnodes; wherein at least a subset of the commands have associated datafields, wherein each of the plurality of commands comprises a pluralityof bit portions of a uniform length, wherein each of the data fieldscomprises a plurality of bit portions having uniform length; wherein adesignated bit of the bit portions of the commands has a first valueindicating that the bit portion is a command; wherein a designated bitof the bit portions of the data fields has a second value indicatingthat the bit portion is a data field, wherein the second value isdifferent than the first value; and configure the audiovisual device topresent the multimedia content according to the first controlinformation.
 22. The audiovisual device of claim 21, wherein at leastone of the commands is a modifier command including a length value andwhich specifies a parameter value applied to all data values within alength distance from the modifier command specified by the length value.23. The audiovisual device of claim 22, wherein the modifier commandspecifies that all data values within the length distance from themodifier command specified by the length value are one of: mandatory; oroptional.
 24. The audiovisual device of claim 21, wherein at least oneof the commands is a modifier command that specifies a parameter valuefor all leaf nodes below a current node position in the tree datastructure.
 25. The audiovisual device of claim 24, wherein the modifiercommand specifies that all data values below the current node positionin the tree data structure are one of: optional; or mandatory.